NO833763L - OPTICAL FIBER CABLE - Google Patents

Description

The present invention relates to a cable with optical fibers and in particular such a cable which is able to function after it has been exposed to intense light and heat radiation of the type that can occur in connection with a nuclear explosion.

The use of light signals and optical fibers is gradually replacing the use of electric current and conventional metal conductors for the transmission of data and communication signals. The use of optical fibers requires that they be included in cables in such a way that they are protected from environmental stresses and receive acceptable conditions of use. Various cable types have long been constructed, where the optical fiber is protected against the normal stresses caused by the environment and provides conditions of use that are generally satisfactory.

When cables with optical fibers find their way into military applications, requirements arise that the cable must be able to withstand the stresses during and must still be able to operate after a nuclear stress, e.g. after a nuclear weapon explosion. Thus, the cable must be sufficiently robust to be able to withstand both normal environmental stresses, as well as these special conditions of use, i.e. it must be able to

withstand the intense light, the strong gusts of wind and the high temperature that develop during and after a nuclear explosion.

This means that during and after such an explosion, the optical fiber must be able to transmit light, and the cable must be in sufficient condition to withstand the stresses caused by the rubble that is scattered around after the explosion, as well as other normal environmental stresses and user loads.

The purpose of the present invention is therefore to provide a cable with optical fibers particularly suitable for withstanding the stresses of a nuclear explosion, where the optical fiber is protected in such a way that it is neither broken nor melted during such events.

The invention comprises an optical cable of any type, but primarily suitable to withstand normal environmental stresses and conditions of use. In addition, a heat-insulating material is placed around the cable to protect it from the extreme heat generated during and after a nuclear explosion. Advantageously, a flame-retardant sacrificial sheath can be placed and fibers 18. A conventional sheath 22 is formed around the tensile elements 20, which holds the tensile elements 20 in place and provides additional protection for the fibers. The sheath 22 may consist of paper or polyester wrapped around the tension elements 20 and an extruded sheath. This particular structure is not shown as it is largely conventional. It should be emphasized that other casing constructions can be used.

According to the present invention, the jacket 22 is wrapped with the heat-insulating material 12, which has a sufficient thickness to withstand the expected heat levels that occur during a nuclear explosion. The heat insulating material 12 is preferably a glass fiber material which is usually referred to as fiberglass. The fiberglass is preferably covered with a fluorocarbon, which acts as a friction-reducing material, e.g. Teflon. In this way, frictional resistance is reduced during the production of the cable. The fiberglass can be obtained in the form of a yarn or a ribbon, and can be used in both of these forms. If desired, the fiberglass yarn can be braided into a woven material, and can be used in this form. The fiberglass is preferably helically wound around the sheath 22. Other materials suitable for use as heat-insulating material 12 are an organic tape, e.g. of aramid or polytetrafluoroethylene.

The flame-retardant sacrificial sheath 14 is extruded over the fiberglass 12 and can be a flame-retardant polyurethane material, such as e.g. sold under the trade name ESTANE sold by B.F. Goodrich or the material HALAR sold by Allied Chemical. HALAR is a fluoropolymer resin containing a one-to-one alternating copolymer of ethylene and chlorotrifluoroethylene. This material is ablative, as it evaporates at high heat, but other types of flame retardant materials can also be used. For example materials that char instead of evaporating can be used.

In some cases, depending on the operating conditions, the use of a sacrificial sheath can be avoided. In such cases, the heat insulating material must be made thicker to help absorb the heat generated at the onset of the explosion.

During a nuclear explosion, a thermal flash is first developed in the form of intense light with a duration of between 12 and 20 seconds. This light will ignite the illuminated surfaces of the sacrificial mantle 14 and cause it to vaporize or char. After this flash comes a strong wind that will extinguish the combustion of the mantle. Then, the intense heat that follows the explosion will be endured by insulating material 12, which is still practically intact like the cable 10. Since the cable 10 is intact, it can still operate under normal ambient conditions and conditions of use for which it was designed.

Claims (10)

1. Cable with at least one optical fiber surrounded by a protective sheath, characterized in that a heat-insulating material (12) surrounds the sheath. 2. Cable according to claim 1, characterized in that the heat-insulating material (12) is surrounded by a sacrificial sheath (14) which can be flame retardant. 3. Cable according to claim 1 or .2, characterized in that the heat-insulating material comprises fiberglass (12). 4. Cable according to claim 1 or 2, characterized in that the heat-insulating material is an organic band selected from a group of substances comprising aramid and polytetrafluoroethylene. 5. Cable according to claim 3, characterized in that the fiberglass is wound helically around the sheath. 6. Cable according to claim 3, characterized in that the fiberglass is braided around the sheath. 7. Cable according to claim 3, characterized in that the fiberglass has the form of a band that is wrapped around the sheath. 8. Cable according to claim 2, characterized in that the flame-retardant jacket consists of polyurethane. 9. Cable according to claim 2, characterized in that the flame-retardant jacket is ablative. 10. Cable according to claim 2, characterized in that the flame-retardant jacket chars or evaporates when exposed to strong heat.